Brooding crustaceans in a highly fragmented habitat: the genetic structure of Mediterranean marine cave-dwelling mysid populations

Habitat fragmentation and climate change are two major threats on biodiversity. Fragmentation limits the number of patches and their decreased connectivity cannot always maintain populations at dynamic equilibrium. The natural extreme fragmentation of marine cave habitats represents an opportunity t...

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Bibliographic Details
Published in:Molecular ecology 2006-11, Vol.15 (13), p.4123-4140
Main Authors: LEJEUSNE, C, CHEVALDONNÉ, P
Format: Article
Language:English
Subjects:
Animals
Biodiversity
caves
Climate
Climate change
coastal hydrodynamics
Crustacea
Crustacea - genetics
Crustaceans
cytochrome-c oxidase
DNA, Mitochondrial
Electron Transport Complex IV - genetics
Environment
Female
Gene Flow
genes
Genetic Variation
Genetics, Population
genotype-environment interaction
habitat fragmentation
Habitats
heat tolerance
Hemimysis
Hemimysis speluncola
Male
Marine
marine environment
Mediterranean Region
metapopulation
Mysidacea
nucleotide sequences
Phylogeny
population dynamics
Population genetics
population structure
regional warming
water flow
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Summary:Habitat fragmentation and climate change are two major threats on biodiversity. Fragmentation limits the number of patches and their decreased connectivity cannot always maintain populations at dynamic equilibrium. The natural extreme fragmentation of marine cave habitats represents an opportunity to understand how these processes interact. The hypothesis of a low gene flow among populations due to a high level of fragmentation was tested by analysing sequence variation in a fragment of the mitochondrial gene of the cytochrome oxidase subunit I in 170 individuals (23 localities across the NW Mediterranean) of two marine cave-dwelling mysids of the genus Hemimysis. The species Hemimysis margalefi recently replaced its congener Hemimysis speluncola, a species shift that could be related to the warming of the Mediterranean Sea and to differences in their thermal tolerances. There were too few H. speluncola samples to further discuss their genetic structuring, but for H. margalefi, the present study revealed high levels of genetic diversity and genetic structuring, as shown by the eight genetically distinct groups identified. The Croatian group might constitute a sibling species due to a strong divergence (15%). Nevertheless, these groups present reduced but orientated gene flow according to the general circulation in the Mediterranean, and fit a stepping-stone model. At local scale (Marseille area, France), gene flow among caves is dependent on unexpected local hydrodynamic barriers, that determine metapopulation sizes. Through the example of mysid species inhabiting marine caves, the present work confirms the strong influence of habitat disjunction (natural fragmentation) on population structure, and stresses the importance of coastal geomorphological features in inducing complex interactions between the circulation of water masses and the circulation of genes.
ISSN:0962-1083
1365-294X
DOI:10.1111/j.1365-294X.2006.03101.x